DE3421734A1 - METHOD FOR PROTECTING INFRARED RADIATING DESTINATIONS, ESPECIALLY SHIPS, FROM AIRCRAFT EQUIPPED WITH INFRARED STEERING HEADS - Google Patents

Description

description

It is already known that infrared-radiating targets, like ships, protect against missiles equipped with infrared guided search heads by standing next to or Above the target, however, in the area of the optics of the infrared steering seeker head, an infrared decoy that sets a higher one Has infrared radiation power as the endangered target. Infrared target clouds are particularly suitable for this, caused by the shooting of a flammable throwing device, namely a so-called pyrotechnic flare, loaded throwing body, for example from conventional throwing cups, dismantling of the throwing body in a certain distance from the target and simultaneous ignition and distribution of the burning throwing material will. In addition to these decoy clouds, there are also infrared flares. However, these are only point sources and therefore less suitable for deception than the decoy clouds, the large-volume and only slowly sinking surface emitters represent with high radiation power. The latter are therefore preferred for initiating disruptive measures.

The formation of a single infrared decoy cloud is as a disruptive measure for smaller targets, such as S-boats, generally fully sufficient, but harbors in the case of larger targets, for example frigates, disadvantages and uncertainties in themselves, at least partly due to the way the infrared steering search heads work.

These search heads have optics that at the beginning of the so-called search phase, which is usually at a distance of about Starts 10 to 15 km from the target, relatively large opening angles so that they have, for example, a search range of about 3000 to 5000 m in azimuth and about 300 to 500 m in elevation. After recognizing the

Target turns the steering seeker in the course of further Anflugs the missile to the target on what is also known as lock-on, and with this operation, the angle of the optics of the steering seeker both in ° azimuth decreased as well in the elevation very strong. At a distance of about 5 to 8 km, at which the target is usually locked, the area covered by the search window of the steering seeker head is then only about 100 m in azimuth and about 50 m in elevation. This area then becomes smaller and smaller in the course of the further approach of the missile up to the impact. The infrared decoy cloud to be created to deflect the missile must therefore only be about 40 to 50 m to the side of the target's center of gravity and only about 25 to 30 m above the boat so that it can still be seen from the already reduced viewing angle of the optics of the infrared seeker head is detected. In such a case, in an S-boat, the new radiation center of gravity formed by the infrared decoy cloud and the S-boat is just outside the boat, and it shifts more and more towards the decoy in the course of the increasing approach of the missile, as the decoy cloud has a significantly higher infrared radiation power compared to the actual target. In the case of small ships, such as submarines, the missile is therefore generally deflected in a fully effective manner by the formation of such a single decoy cloud.

On the other hand, the situation is different for larger ships, such as a frigate, which is normally the case has a length of about 120 m. Here the decoy to be formed must still be in the area of the ship so that it can from the optics of the infrared steering seeker head, which is already connected to the target of the missile can still be detected. The missile is thereby formed by the decoy in the best case only be deflected so far that it only more or less just overflies the threatened ship. In such a case, however, there is a risk that the missile via its proximity fuse to the Ex-

plosion is brought about, whereby the sensitive deck superstructures, such as antennas, sensors and the like, are destroyed. This would have a severe impairment, or even one complete loss of operational capability of the ship.

The greater the ship's size, the less maneuverable it is. For example, S-boats can result their lightness and maneuverability after setting the infrared decoy also perform evasive maneuvers and thus increase the distance to the decoy. Larger ships can be used in the available For a short time, however, no longer accomplish such maneuvers, so that these practically alone on the set Pseudo targets are instructed as protective measures. This generally applies to ships with a water displacement of around 600 t, and thus already for corvettes.

The above explanations show that the conventional formation of an infrared decoy cloud under certain circumstances smaller targets, such as submarines, with infrared steering search heads Equipped missiles can be adequately protected, but not larger targets, for example Ships like corvettes and especially frigates.

Based on the well-known formation of infrared decoy clouds to protect infrared-radiating targets, in particular of ships, the invention is therefore based on the object of creating a new method of this type, through which the respective goals can be better and more securely protected and, above all, an adequate one Protection of larger goals, in particular larger ships, can be achieved, and this object is achieved according to the invention now solved by the resulting from claim 1 method. Preferred embodiments of this method can be found in sub-claims 2 to 6.

The essential element of the invention therefore consists in such an application of a conventional surface radiator Kind that at the beginning of the disturbance maneuver as close as possible to the target, for example to the ship to be protected, a first ° and the infrared decoy cloud that can be detected by the optics of the infrared steering seeker head is formed, whereupon one in each case one under such temporal and spatial displacement subsequent new decoy cloud forms in such a way that at least the previous decoy cloud has its radiation power maintained until the new decoy cloud has fully developed its radiation power, so that at least Over a short period of time, an effectively coherent transition or, better said, an overlap between the two consecutive infrared decoy clouds consists. This creates a chain link (previous decoy cloud) to chain link (subsequent decoy cloud) propagating chain of a further new decoy cloud, the continuously detected by the optics of the infrared steering seeker head so that the missile is increasingly pulled further away from the threatened target. Depending on the time sequence and the number of missed ones In this way, missiles can therefore also prevent larger ships from being attacked by missiles equipped with infrared steering search heads to be protected. The overlap times can of course also be longer, so that under certain circumstances not only two, but several clouds are burning at the same time and theirs Develop an effect as a dummy target.

The method according to the invention can be carried out so that one is responsible for the formation of the propagating chain missiles required from infrared decoy targets from several launch tubes, each loaded with one missile, one after the other, command-controlled, fires at ever increasing distances, preferably but a single and command-controlled launch tube loaded with several projectiles in a row is used. The use of such a single launch tube in which the individual projectiles are stacked

are arranged one behind the other, has the advantage, among other things, that there is a substantial saving in weight and Space for the system required for shooting results in what

is especially important because warships in general 5

very limited in terms of their capacity in terms of space and weight and are usually used to the limit anyway. The main advantage of the application of a single launch tube, however, lies in the fact that there is a results in increasingly longer leadership in the launch tube. The consequence of such a longer tour is both a higher one Accuracy as well as higher acceleration and an associated increase in flight distance.

Firing from a single launch tube therefore achieves essentially two things. The bigger and bigger The increasing acceleration when firing the individual projectiles enables, on the one hand, the catching of the otherwise for the increasingly greater distance required higher amount of propellant charge to a whole considerable part. This means a reduction in recoil and thus the load on the weapon and ammunition, what in addition to the resulting weight savings, it is also associated with structural and cost-related advantages. On the other hand, the spread, which increases with increasing flight distance, is due to the increasingly longer guidance in the launch tube at the same time compensating for increasing accuracy. This can therefore be an optimal way propagating chain of consecutive Infrared decoy clouds form a relatively narrow spacing with effective interlocking from each other and make a relatively neat straight line.

for the protection of larger ships, such as frigates, it is generally sufficient if one according to the invention Process five to nine in sequence, preferably seven

ben, shoots projectiles, preferably using a single launch tube for this purpose, which is connected to such a Number of debris is loaded. Used to shoot the required row of individual projectiles no single launch tube, then the special additional advantages mentioned above will of course not result, and it must in such a case, namely when using several individual launch tubes, by suitable constructive Measures are taken to ensure that the essential for the success of the process according to the invention clean Chain of successive new infrared decoy clouds results.

The throwing bodies to be used can, including the throwing means contained therein and that for their firing required launch tubes be constructed in the usual way. What is essential, however, is that what is contained in them Throwing means after ignition results in an infrared decoy cloud with an infrared radiation output which is higher is than that of the threatened target, and that the means of throwing this radiation output over a proportionate long and defined burning time as well as a low rate of descent. As a result of achieving of a clean effect needed, reproductive In a chain of successive further infrared decoy clouds, you have to create the new infrared decoy cloud form under a time sequence that is sufficient with the previously formed infrared decoy cloud Burn time overlap results. Without such a burning time overlap it could happen that the missile's search head, which has already been set to the decoy, either swivels back to the threatened target, / if this is still within his viewing angle, or that the entire search maneuver starts again after returning to the search phase.

For the reasons set out above, the further

new infrared decoy target cloud are therefore formed by a time sequence that results with the previously formed infrared decoy cloud, an internal time overlap of at least 1 to 2 seconds. Longer overlapping times don't hurt. As a rule, however, two thirds of the burning time of the individual decoy clouds should not be exceeded because otherwise more than three clouds will shine at the same time and the impression that the decoy target is moving away is too blurred. 10

The optimal burning time and therefore the service life of a single target is sufficient, taking into account a Duration of the entire fault measure and the required overlap time between 9 and 15 seconds. The burn time of the throwing means must therefore be at least 9 seconds and should not exceed 15 seconds. Also must its rate of descent can be very low, otherwise the distance to the next cloud may be so great becomes that the following cloud is no longer detected by the infrared seeker head, or at least both clouds so are far apart that they no longer represent a single target. These conditions are made by a Flammable throwing means met, as described in BE-PS 874 835.

The time sequence under which the individual projectiles are fired is not only dependent on the burning time of the individual Decoys, but also on the speed and distance of the missile to be deflected as well as the Size, direction of travel and speed of the object to be protected. Usually this time sequence is chosen so that at the earliest every 3 and at the latest every 13 seconds another new infrared decoy cloud as part of it the propagating chain of new infrared decoy clouds is formed. In exceptional cases, however, a shorter time sequence is also possible, for example down up to a second and less. Such a short time sequence may be required when an approaching missile

is recognized too late, so that long time sequences are no longer possible. In the extreme case, therefore, all objects are thrown out Fired immediately one after the other, but then only one elongated path from each results in decoy clouds blooming in quick succession and thus practically no decoy any more wandering away. Since the However, the missile controls the radiation center, which is formed by the actual target and the decoy, he is at least distracted to such an extent that the goal is no longer or only slightly in such a case endangered is.

The essential element of the method according to the invention is therefore according to the above, that one

¹ ^ in contrast to the known methods for protecting an infrared-radiating target from missiles equipped with infrared steering seekers, not only a single infrared decoy cloud or several, but not effectively connected infrared decoy clouds, but one after the other among such temporal and spatial displacement generates a propagating chain of successive and effectively connected infrared decoy clouds that results in a decoy that is constantly moving further away from the threatened target. Conventional projectiles, launching systems and other devices required for this purpose can be used for this purpose, but these must be redesigned if necessary. A device particularly suitable for this can be found in the patent application filed by the same applicant with the internal file number BU 18 at the same time as this application.

The beginning of the process to be initiated by the method according to the invention Disturbing maneuvers and also the time between the individual kills are normally of a computer determined by inputting the above-mentioned data. All of this must be interpreted in such a way that each

The previous decoy cloud burns for at least a certain time and thus develops its effect, while the each subsequent new infrared decoy cloud reaches its maximum effectiveness. Between the two clouds is therefore an at least short-term, effective overlap is required, which is at least about 1 to 2 seconds must be. The successive infrared decoy clouds are usually in their focus of action about 15 to 25 m apart. The decoy moves about 15 to 25 m further for each projectile launched away from the threatened ship. A prerequisite for effective protection is that the decoy formed during the The necessary protective measures do not expire at any time and of course not from the previous decoy target may be far away, otherwise it will no longer be in the viewing angle of the infrared steering search head of the respective missile lies and is therefore no longer covered by this. If the decoy goes out, the infrared seeker head would Pivot back to the actual target if this is still within its respective viewing angle. The same thing happens if there is a gap in the sequence of the disturbance maneuver. The decoy that lights up too late could then already be outside the viewing angle of the optics of the infrared steering seeker head, whereby the entire Diversion would lose its effect. Of course, when using a simple one, namely not position-stabilized Launching tube, the individual projectiles only ever shot from the exact same position of the ship because there is a precisely running line of consecutive Decoys must be formed, which can not arise without appropriate control. Depending on For this reason, too, the size of the ship and the extent of the swell can differ in a rolling ship Shooting times for the individual projectiles result. With a computer-based control of the launch on the other hand, such irregularities can usually be compensated for automatically.

Claims (6)

BU-17 Buck Chemisch-Technische Werke GmbH & Co. D - 7347 Bad Ueberkingen The Plessey Company PLC, Ilford, Essex, Great Britain Procedure for the protection of infrared-radiating targets, in particular from ships, in front of missiles equipped with infrared guided search heads Claims 25 (ly procedure for the protection of infrared-radiating targets, in particular from ships, in front of missiles equipped with infrared guided search heads, whereby one is next to the target and in the area of the optics of the steering seeker head by launch a projectile loaded with a combustible material from a launch tube installed on the threatened target, dismantling of the projectile body and simultaneous ignition and distributing the throwing means an infrared decoy cloud with compared to the threatened target forms higher infrared radiation power, characterized that one after the other several projectiles under such temporal and spatial displacement fires and with ignition and distribution of what is in it Throwing means decomposed that a chain propagating from the previous decoy cloud of successive further new infrared decoy target clouds are created and thus one that is constantly moving further away from the threatened target Decoy is formed. 2. The method according to claim 1, characterized in that one has a plurality of projectiles single launcher tube loaded in series used. 3. The method according to claim 1 or 2, characterized characterized in that one shoots five to nine projectiles, preferably seven projectiles, one after the other or a single launch tube loaded with such a number of projectiles is used for firing. 4. The method according to any one of the preceding claims, characterized in that the each time another new infrared decoy cloud forms under a time sequence that corresponds to the previously formed infrared decoy cloud results in a burn time overlap of at least 1 to 2 seconds. 5. The method according to any one of the preceding claims, characterized in that throwing bodies are used, the throwing means of which one after ignition Infrared decoy cloud with a burning time of minde-QQ at least 9 to a maximum of 15 seconds. 6. The method according to claim 5, characterized in that the projectile body under a Sequence of time shoots and dismantled with ignition and distribution of the throwing means located therein, that at the earliest after 3 seconds and at the latest after 13 seconds another new infrared decoy cloud as part of the planting chain of new infrared decoy clouds is formed.